Integrated piezoresistive and piezoelectric fusion force sensor

ABSTRACT

Described herein is a ruggedized microelectromechanical (“MEMS”) force sensor including both piezoresistive and piezoelectric sensing elements and integrated with complementary metal-oxide-semiconductor (“CMOS”) circuitry on the same chip. The sensor employs piezoresistive strain gauges for static force and piezoelectric strain gauges for dynamic changes in force. Both piezoresistive and piezoelectric sensing elements are electrically connected to integrated circuits provided on the same substrate as the sensing elements. The integrated circuits can be configured to amplify, digitize, calibrate, store, and/or communicate force values electrical terminals to external circuitry.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. patent application Ser. No. 16/485,026, filed on Aug. 9, 2019, which is a 35 USC 371 national phase application of PCT/US2018/017572 filed on Feb. 9, 2018, which claims the benefit of U.S. provisional patent application No. 62/456,699, filed on Feb. 9, 2017, and entitled “INTEGRATED DIGITAL FORCE SENSOR,” and U.S. provisional patent application No. 62/462,559, filed on Feb. 23, 2017, and entitled “INTEGRATED PIEZORESISTIVE AND PIEZOELECTRIC FUSION FORCE SENSOR,” the disclosures of which are expressly incorporated herein by reference in their entireties.

FIELD OF TECHNOLOGY

The present disclosure relates to microelectromechanical (“MEMS”) force sensing with piezoresistive and piezoelectric sensor integrated with complementary metal-oxide-semiconductor (“CMOS”) circuitry.

BACKGROUND

Force sensing touch panels are realized with force sensors underneath the display area with certain sensor array arrangements. These touch panels require the force sensors to provide high quality signals, meaning high sensitivity is essential. Existing MEMS piezoresistive sensors are suitable for such applications and are typically paired with extremely low noise amplifiers due to the low sensitivity of the sensors. Such amplifiers are expensive and tend to consume a lot of power. Piezoelectric sensors are highly sensitive in force sensing applications, but only for dynamic changes in force (i.e., not static forces). Therefore, piezoelectric sensors cannot provide accurate offset information.

Accordingly, there is a need in the pertinent art for a low power, high sensitivity force sensor capable of sensing both static and dynamic force with high sensitivity and accuracy.

SUMMARY

A MEMS force sensor including both piezoresistive and piezoelectric sensing elements on the same chip is described herein. The force sensor can also include integrated circuits (e.g., digital circuitry) on the same chip. In one implementation, the force sensor is configured in a chip scale package (“CSP”) format. A plurality of piezoresistive sensing elements are implemented on the silicon substrate of the integrated circuit chip. In addition, a plurality of piezoelectric elements are disposed between the metal pads and solder bumps, where the force is directly transduced for sensing.

The MEMS force sensor can be manufactured by first diffusing or implanting the piezoresistive sensing elements on a silicon substrate. Then, the standard integrated circuit process (e.g., CMOS process) can follow to provide digital circuitry on the same silicon substrate. The overall thermal budget can be considered such that the piezoresistive sensing elements can maintain their required doping profile. After the integrated circuit process is completed, the piezoelectric layer along with two electrode layers (e.g., a piezoelectric sensing element) are then disposed and patterned on the silicon substrate. Solder bumps are then formed on the metal pads and the wafer is diced to create a chip scale packaged device. The force exerted on the back side of the device induces strain in both the plurality of piezoresistive sensing elements and the plurality of piezoelectric sensing elements, which produce respective output signals proportional to the force. The output signals can be digitized by the integrated circuitry and stored in on-chip buffers until requested by a host device.

An example microelectromechanical (“MEMS”) force sensor is described herein. The MEMS force sensor can include a sensor die configured to receive an applied force. The sensor die has a top surface and a bottom surface opposite thereto. The MEMS force sensor can also include a piezoresistive sensing element, a piezoelectric sensing element, and digital circuitry arranged on the bottom surface of the sensor die. The piezoresistive sensing element is configured to convert a strain to a first analog electrical signal that is proportional to the strain. The piezoelectric sensing element is configured to convert a change in strain to a second analog electrical signal that is proportional to the change in strain. The digital circuitry is configured to convert the first and second analog electrical signals to respective digital electrical output signals.

Additionally, the piezoresistive sensing element can be formed by diffusion or implantation. Alternatively, the piezoresistive sensing element can be formed by polysilicon processes from an integrated circuit process.

Alternatively or additionally, the MEMS force sensor can include a solder ball arranged on the bottom surface of the sensor die. The piezoelectric sensing element can be disposed between the solder ball and the sensor die.

Alternatively or additionally, the MEMS force sensor can include a plurality of electrical terminals arranged on the bottom surface of the sensor die. The respective digital electrical output signals produced by the digital circuitry can be routed to the electrical terminals. The electrical terminals can be solder bumps or copper pillars.

Alternatively or additionally, the digital circuitry can be further configured to use the second analog electrical signal produced by the piezoelectric sensing element and the first analog electrical signal produced by the piezoresistive sensing element in conjunction to improve sensitivity and accuracy. For example, the first analog electrical signal produced by the piezoresistive sensing element can measure static force applied to the MEMS force sensor, and the second analog electrical signal produced by the piezoelectric sensing element can measure dynamic force applied to the MEMS force sensor.

Alternatively or additionally, the MEMS force sensor can include a cap attached to the sensor die at a surface defined by an outer wall of the sensor die. A sealed cavity can be formed between the cap and the sensor die.

Alternatively or additionally, the sensor die can include a flexure formed therein. The flexure can convert the applied force into the strain on the bottom surface of the sensor die.

Alternatively or additionally, a gap can be arranged between the sensor die and the cap. The gap can be configured to narrow with application of the applied force such that the flexure is unable to deform beyond its breaking point.

Alternatively or additionally, the MEMS force sensor can include an inter-metal dielectric layer arranged on the bottom surface of the sensor die. The piezoelectric sensing element can be arranged on the inter-metal dielectric layer.

Alternatively or additionally, the digital circuitry can be further configured to store the respective digital electrical output signals to a buffer.

Other systems, methods, features and/or advantages will be or may become apparent to one with skill in the art upon examination of the following drawings and detailed description. It is intended that all such additional systems, methods, features and/or advantages be included within this description and be protected by the accompanying claims.

BRIEF DESCRIPTION OF THE FIGURES

The components in the drawings are not necessarily to scale relative to each other. Like reference numerals designate corresponding parts throughout the several views. These and other features of will become more apparent in the detailed description in which reference is made to the appended drawings.

FIG. 1A is an isometric view of the top of an example MEMS force sensor according to implementations described herein.

FIG. 1B is an isometric view of the bottom of the MEMS force sensor of FIG. 1 .

FIG. 2 is a cross-sectional view of an integrated p-type MEMS-CMOS force sensor using a piezoresistive sensing element (not to scale) according to implementations described herein.

FIG. 3 is a cross-sectional view of an integrated n-type MEMS-CMOS force sensor using a piezoresistive sensing element (not to scale) according to implementations described herein.

FIG. 4 is a cross-sectional view of an integrated p-type MEMS-CMOS force sensor using a polysilicon sensing element (not to scale) according to implementations described herein.

FIG. 5 is an isometric view of the top of another example MEMS force sensor according to implementations described herein.

DETAILED DESCRIPTION

The present disclosure can be understood more readily by reference to the following detailed description, examples, drawings, and their previous and following description. However, before the present devices, systems, and/or methods are disclosed and described, it is to be understood that this disclosure is not limited to the specific devices, systems, and/or methods disclosed unless otherwise specified, and, as such, can, of course, vary. It is also to be understood that the terminology used herein is for the purpose of describing particular aspects only and is not intended to be limiting.

The following description is provided as an enabling teaching. To this end, those skilled in the relevant art will recognize and appreciate that many changes can be made, while still obtaining beneficial results. It will also be apparent that some of the desired benefits can be obtained by selecting some of the features without utilizing other features. Accordingly, those who work in the art will recognize that many modifications and adaptations may be possible and can even be desirable in certain circumstances, and are contemplated by this disclosure. Thus, the following description is provided as illustrative of the principles and not in limitation thereof.

As used throughout, the singular forms “a,” “an” and “the” include plural referents unless the context clearly dictates otherwise. Thus, for example, reference to “a force sensor” can include two or more such force sensors unless the context indicates otherwise.

The term “comprising” and variations thereof as used herein is used synonymously with the term “including” and variations thereof and are open, non-limiting terms.

Ranges can be expressed herein as from “about” one particular value, and/or to “about” another particular value. When such a range is expressed, another aspect includes from the one particular value and/or to the other particular value. Similarly, when values are expressed as approximations, by use of the antecedent “about,” it will be understood that the particular value forms another aspect. It will be further understood that the endpoints of each of the ranges are significant both in relation to the other endpoint, and independently of the other endpoint.

As used herein, the terms “optional” or “optionally” mean that the subsequently described event or circumstance may or may not occur, and that the description includes instances where said event or circumstance occurs and instances where it does not.

A MEMS force sensor 100 for measuring a force applied to at least a portion thereof is described herein. In one aspect, as depicted in FIG. 1A, the force sensor device 100 includes a substrate 101 and inter-metal dielectric layer (IMD) 102 fabricated on a surface (e.g., bottom surface) of the substrate 101 to form integrated circuits. The substrate 101 can optionally be made of silicon. Optionally, the substrate 101 (and its components such as, for example, boss, mesa, outer wall, flexure(s), etc.) is a single continuous piece of material, i.e., the substrate is monolithic. It should be understood that this disclosure contemplates that the substrate can be made from materials other than those provided as examples. In another aspect, as depicted in FIG. 1B, the MEMS force sensor 100 is formed into a chip scale package with solder bumps 103 and a plurality of piezoresistive sensing elements 104. The solder bumps 103 and the piezoresistive sensing elements 104 can be formed on the same surface (e.g., bottom surface) of the substrate 101 on which the IMD layer 102 is fabricated. The piezoresistive sensing elements 104 are configured to convert a strain to an analog electrical signal (e.g., a first analog electrical signal) that is proportional to the strain on the bottom surface of the substrate 101. The piezoresistive sensing elements 104 detect static forces applied to the MEMS force sensor 100. This disclosure contemplates that the piezoresistive sensing elements 104 can be diffused, deposited, or implanted on the bottom surface of substrate 101.

The piezoresistive sensing elements 104 can change resistance in response to deflection of a portion of the substrate 101. For example, as strain is induced in the bottom surface of the substrate 101 proportional to the force applied to the MEMS force sensor 100, a localized strain is produced on a piezoresistive sensing element such that the piezoresistive sensing element experiences compression or tension, depending on its specific orientation. As the piezoresistive sensing element compresses and tenses, its resistivity changes in opposite fashion. Accordingly, a Wheatstone bridge circuit including a plurality (e.g., four) piezoresistive sensing elements (e.g., two of each orientation relative to strain) becomes unbalanced and produces a differential voltage (also sometimes referred to herein as the “first analog electrical signal”) across the positive signal terminal and the negative signal terminal. This differential voltage is directly proportional to the force applied to the MEMS force sensor 100. As described below, this differential voltage can be received at and processed by digital circuitry (e.g., as shown in FIGS. 2-5 ). For example, the digital circuitry can be configured to, among other functions, convert the first analog electrical signal to a digital electrical output signal.

Example MEMS force sensors using piezoresistive sensing elements are described in U.S. Pat. No. 9,487,388, issued Nov. 8, 2016 and entitled “Ruggedized MEMS Force Die;” U.S. Pat. No. 9,493,342, issued Nov. 15, 2016 and entitled “Wafer Level MEMS Force Dies;” U.S. Patent Application Publication No. 2016/0332866 to Brosh et al., filed Jan. 13, 2015 and entitled “Miniaturized and ruggedized wafer level mems force sensors;” and U.S. Patent Application Publication No. 2016/0363490 to Campbell et al., filed Jun. 10, 2016 and entitled “Ruggedized wafer level mems force sensor with a tolerance trench,” the disclosures of which are incorporated by reference in their entireties.

In addition, the MEMS force sensor 100 includes a plurality of piezoelectric sensing elements 105. The piezoelectric sensing elements 105 are located between the solder bumps 103 and the IMD 102. For example, a piezoelectric sensing element 105 can be formed on the IMD layer 102, and the solder bump 103 can be formed over the piezoelectric sensing element 105. The arrangement of a piezoelectric sensing element 105 and the IMD layer 102 is shown in FIGS. 2-4 . Referring again to FIGS. 1A-1B, the piezoelectric sensing elements 105 are configured to convert a change in strain to an analog electrical signal (e.g., a second analog electrical signal) that is proportional to the change strain on the bottom surface of the substrate 101. The piezoelectric sensing elements 105 sense dynamic forces applied to the MEMS force sensor 100. The second analog electrical signal can be routed to digital circuitry (e.g., as shown in FIGS. 2-5 ) arranged on the bottom surface of the substrate 101. For example, the digital circuitry can be configured to, among other functions, convert the second analog electrical signal to a digital electrical output signal. Accordingly, the digital circuitry can be configured to convert the first and second analog electrical signals to respective digital electrical output signals. Additionally, the digital circuitry can be configured to store the respective digital electrical output signals in a buffer such as an on-chip buffer.

In one implementation, as depicted in FIG. 2 , the cross section of a MEMS force sensor device is shown. The force sensor device of FIG. 2 is a MEMS force sensor using an integrated p-type MEMS-CMOS force sensor with a piezoresistive sensing element. The p-type silicon substrate 201 is a CMOS chip with both an n-type metal-oxide-semiconductor (nMOS) transistor 210 and a p-type metal-oxide-semiconductor (pMOS) transistor 211 fabricated on it. The p-type silicon substrate 201 can be a single continuous piece of material, i.e., the substrate can be monolithic. The nMOS source/drain 208 and pMOS source/drain 209 are formed through diffusion or implantation. As shown in FIG. 2 , the pMOS source/drain 209 reside in an n-well region 205, which receives a voltage bias through a highly-doped n-type implant 215. Further, a gate contact 207 (e.g., poly silicon gate) forms the channel required for each of the nMOS transistor 210 and pMOS transistor 211. It should be understood, however, that similar CMOS processes can be adapted to other starting materials, such as an n-type silicon substrate. Additionally, although a silicon substrate is provided as an example, this disclosure contemplates that the substrate can be made from a material other than silicon. This disclosure contemplates that the MEMS force sensor can include a plurality of nMOS and pMOS devices. The nMOS and pMOS devices can form various components of the digital circuitry (e.g., CMOS circuitry). The digital circuitry can optionally include other components, which are not depicted in FIG. 2 , including, but not limited to, bipolar transistors; metal-insulator-metal (“MIM”) and metal-oxide-semiconductor (“MOS”) capacitors; diffused, implanted, and polysilicon resistors; and/or diodes. The digital circuitry can include, but is not limited to, one or more of a differential amplifier or buffer, an analog-to-digital converter, a clock generator, non-volatile memory, and a communication bus. For example, the digital circuitry can include an on-chip buffer for storing the respective digital electrical output signals.

In addition to the nMOS and pMOS transistors 210 and 211 shown in FIG. 2 , a lightly doped n-type piezoresistive sensing element 204 and a heavily doped n-type contact region 203 are formed on the same p-type silicon substrate 201. In other words, the piezoresistive sensing element and digital circuitry can be disposed on the same monolithic substrate. Accordingly, the process used to form the piezoresistive sensing element can be compatible with the process used to form the digital circuitry. The lightly doped n-type piezoresistive sensing element 204 and heavily doped n-type contact region 203 can be formed by way of either diffusion, deposition, or implant patterned with a lithographic exposure process. The MEMS force sensor can also include a piezoelectric sensing element 105, which can be disposed on the IMD 102 layer and underneath the solder ball 103. The piezoelectric sensing element 105 can be formed after completion of the integrated circuit process. Metal 212 and contact 213 layers can be provided to create electrical connections between nMOS and pMOS transistors 210 and 211, piezoresistive sensing element 204, and piezoelectric sensing element 105. Accordingly, the MEMS force sensor includes a piezoresistive sensing element, a piezoelectric sensing element, and digital circuitry all on the same chip.

In another implementation, as depicted in FIG. 3 , the cross section of a MEMS force sensor device is shown. The force sensor device of FIG. 3 is a MEMS force sensor using an integrated n-type MEMS-CMOS force sensor with a piezoresistive sensing element. The p-type silicon substrate 201 is a CMOS chip with both nMOS transistor 210 and pMOS transistor 211 fabricated on it. The p-type silicon substrate 201 can be a single continuous piece of material, i.e., the substrate can be monolithic. The nMOS source/drain 208 and pMOS source/drain 209 are formed through diffusion or implantation. As shown in FIG. 3 , the pMOS source/drain 209 reside in an n-well region 205, which receives a voltage bias through a highly-doped n-type implant 215. Further, a gate contact 207 (e.g., poly silicon gate) forms the channel required for each of the nMOS transistor 210 and pMOS transistor 211. It should be understood, however, that similar CMOS processes can be adapted to other starting materials, such as an n-type silicon substrate. Additionally, although a silicon substrate is provided as an example, this disclosure contemplates that the substrate can be made from a material other than silicon. This disclosure contemplates that the MEMS force sensor can include a plurality of nMOS and pMOS devices. The nMOS and pMOS devices can form various components of the digital circuitry (e.g., CMOS circuitry). The digital circuitry can optionally include other components, which are not depicted in FIG. 3 , including, but not limited to, bipolar transistors; metal-insulator-metal (“MIM”) and metal-oxide-semiconductor (“MOS”) capacitors; diffused, implanted, and polysilicon resistors; and/or diodes. The digital circuitry can include, but is not limited to, one or more of a differential amplifier or buffer, an analog-to-digital converter, a clock generator, non-volatile memory, and a communication bus. For example, the digital circuitry can include an on-chip buffer for storing the respective digital electrical output signals.

In addition to the nMOS and pMOS transistors 210 and 211 shown in FIG. 3 , a lightly doped p-type piezoresistive sensing elements 304 and a heavily doped n-type contact region 303 are formed on the same p-type silicon substrate 201 inside an n-well 314. In other words, the piezoresistive sensing element and digital circuitry can be disposed on the same monolithic substrate. Accordingly, the process used to form the piezoresistive sensing element can be compatible with the process used to form the digital circuitry. The n-well 314, lightly doped n-type piezoresistive sensing element 304, and heavily doped n-type contact region 303 can be formed by way of either diffusion, deposition, or implant patterned with a lithographic exposure process. The MEMS force sensor can also include a piezoelectric sensing element 105, which is disposed on the IMD 102 layer and underneath the solder ball 103. The piezoelectric sensing element 105 can be formed after completion of the integrated circuit process. Metal 212 and contact 213 layers can be provided to create electrical connections between the nMOS and pMOS transistors 210 and 211, piezoresistive sensing element 304, and piezoelectric sensing element 105. Accordingly, the MEMS force sensor includes a piezoresistive sensing element, a piezoelectric sensing element, and digital circuitry all on the same chip.

In yet another implementation, as depicted in FIG. 4 , the cross section of a MEMS force sensor device is shown. The force sensor device of FIG. 4 is an MEMS force sensor using an integrated p-type MEMS-CMOS force sensor with a polysilicon sensing element. The p-type silicon substrate 201 is a CMOS chip with both nMOS transistor 210 and pMOS transistor 211 fabricated on it. The p-type silicon substrate 201 can be a single continuous piece of material, i.e., the substrate can be monolithic. The nMOS source/drain 208 and pMOS source/drain 209 are formed through diffusion or implantation. As shown in FIG. 4 , the pMOS source/drain 209 reside in an n-well region 205, which receives a voltage bias through a highly-doped n-type implant 215. Further, a gate contact 207 (e.g., poly silicon gate) forms the channel required for each of the nMOS transistor 210 and pMOS transistor 211. It should be understood, however, that similar CMOS processes can be adapted to other starting materials, such as an n-type silicon substrate. Additionally, although a silicon substrate is provided as an example, this disclosure contemplates that the substrate can be made from a material other than silicon. This disclosure contemplates that the MEMS force sensor can include a plurality of nMOS and pMOS devices. The nMOS and pMOS devices can form various components of the digital circuitry (e.g., CMOS circuitry). The digital circuitry can optionally include other components, which are not depicted in FIG. 4 , including, but not limited to, bipolar transistors; metal-insulator-metal (“MIM”) and metal-oxide-semiconductor (“MOS”) capacitors; diffused, implanted, and polysilicon resistors; and/or diodes. The digital circuitry can include, but is not limited to, one or more of a differential amplifier or buffer, an analog-to-digital converter, a clock generator, non-volatile memory, and a communication bus. For example, the digital circuitry can include an on-chip buffer for storing the respective digital electrical output signals.

In addition to the nMOS and pMOS transistors 210 and 211 of FIG. 4 , a doped piezoresistive sensing element 404 and a silicided contact region 403 are formed with the same polysilicon gate material used for the nMOS transistor 210 and pMOS transistor 211. In other words, the piezoresistive sensing element and digital circuitry can be disposed on the same monolithic substrate. The MEMS force sensor can also include a piezoelectric sensing element 105, which is disposed on the IMD layer 102 and underneath solder ball 103. The piezoelectric sensing element 105 can be formed after completion of the integrated circuit process. Metal 212 and contact 213 layers can be used to create electrical connections between nMOS and pMOS transistors 210 and 211, piezoresistive sensing element 404, and piezoelectric sensing element 105. Accordingly, the MEMS force sensor includes a piezoresistive sensing element, a piezoelectric sensing element, and digital circuitry all on the same chip.

In addition to the implementations described above, a stress amplification mechanism can be implemented on the substrate of the MEMS force sensor. For example, as depicted in FIG. 5 , the MEMS force sensor 500 includes a substrate 101 with a cap 501 bonded to it. The substrate 101 and cap 501 can be bonded at one or more points along the surface formed by an outer wall 504 of the substrate 101. In other words, the substrate 101 and cap 501 can be bonded at a peripheral region of the MEMS force sensor 500. It should be understood that the peripheral region of the MEMS force sensor 500 is spaced apart from the center thereof, i.e., the peripheral region is arranged near the outer edge of the MEMS force sensor 500. Example MEMS force sensors where a cap and sensor substrate are bonded in peripheral region of the MEMS force sensor are described in U.S. Pat. No. 9,487,388, issued Nov. 8, 2016 and entitled “Ruggedized MEMS Force Die;” U.S. Pat. No. 9,493,342, issued Nov. 15, 2016 and entitled “Wafer Level MEMS Force Dies;” U.S. Patent Application Publication No. 2016/0332866 to Brosh et al., filed Jan. 13, 2015 and entitled “Miniaturized and ruggedized wafer level mems force sensors;” and U.S. Patent Application Publication No. 2016/0363490 to Campbell et al., filed Jun. 10, 2016 and entitled “Ruggedized wafer level mems force sensor with a tolerance trench,” the disclosures of which are incorporated by reference in their entireties.

The cap 501 can optionally be made of glass (e.g., borosilicate glass) or silicon. The substrate 101 can optionally be made of silicon. Optionally, the substrate 101 (and its components such as, for example, the mesa, the outer wall, the flexure(s), etc.) is a single continuous piece of material, i.e., the substrate is monolithic. It should be understood that this disclosure contemplates that the cap 501 and/or the substrate 101 can be made from materials other than those provided as examples. This disclosure contemplates that the cap 501 and the substrate 101 can be bonded using techniques known in the art including, but not limited to, silicon fusion bonding, anodic bonding, glass frit, thermo-compression, and eutectic bonding.

In FIG. 5 , the cap 501 is made transparent to illustrate the internal features. An inter-metal dielectric layer (IMD) 102 can be fabricated on a surface (e.g., bottom surface) of the substrate 101 to form integrated circuits. Additionally, a deep trench 502 is formed on the substrate 101 and serves as a stress amplification mechanism. The trench 502 can be etched by removing material from the substrate 101. Additionally, the trench 502 defines the outer wall 504 and mesa 503 of the substrate 101. The base of the trench 502 defines a flexure. The piezoelectric sensing elements can be formed on a surface of the flexure, which facilitates stress amplification. In FIG. 5 , the trench 502 is continuous and has a substantially square shape. It should be understood that the trench can have other shapes, sizes, and/or patterns than the trench shown in FIG. 5 , which is only provided as an example. Optionally, the trench 502 can form a plurality of outer walls and/or a plurality of flexures. An internal volume can be sealed between the cap 501 and substrate 101 (i.e., sealed cavity). The sealed cavity can be sealed between the cap 501 and the substrate 101 when bonded together. In other words, the MEMS force sensor 500 can have a sealed cavity that defines a volume entirely enclosed by the cap 501 and the substrate 101. The sealed cavity is sealed from the external environment. Example MEMS force sensors having a cavity (e.g., trench) that defines a flexible sensing element (e.g., flexure) are described in U.S. Pat. No. 9,487,388, issued Nov. 8, 2016 and entitled “Ruggedized MEMS Force Die;” U.S. Pat. No. 9,493,342, issued Nov. 15, 2016 and entitled “Wafer Level MEMS Force Dies;” U.S. Patent Application Publication No. 2016/0332866 to Brosh et al., filed Jan. 13, 2015 and entitled “Miniaturized and ruggedized wafer level mems force sensors;” and U.S. Patent Application Publication No. 2016/0363490 to Campbell et al., filed Jun. 10, 2016 and entitled “Ruggedized wafer level mems force sensor with a tolerance trench,” the disclosures of which are incorporated by reference in their entireties.

A gap (e.g., air gap or narrow gap) can be arranged between the cap 501 and the mesa 503, which is arranged in the central region of the MEMS force sensor 500. The narrow gap serves as a force overload protection mechanism. The gap can be within the sealed cavity. For example, the gap can be formed by removing material from the substrate 101. Alternatively, the gap can be formed by etching a portion of the cap 501. Alternatively, the gap can be formed by etching a portion of the substrate 101 and a portion of the cap 501. The size (e.g., thickness or depth) of the gap can be determined by the maximum deflection of the flexure, such that the gap between the substrate 101 and the cap 501 will close and mechanically stop further deflection before the flexure is broken. The gap provides an overload stop by limiting the amount by which the flexure can deflect such that the flexure does not mechanically fail due to the application of excessive force.

Example MEMS force sensors designed to provide overload protection are described in U.S. Pat. No. 9,487,388, issued Nov. 8, 2016 and entitled “Ruggedized MEMS Force Die;” U.S. Pat. No. 9,493,342, issued Nov. 15, 2016 and entitled “Wafer Level MEMS Force Dies;” U.S. Patent Application Publication No. 2016/0332866 to Brosh et al., filed Jan. 13, 2015 and entitled “Miniaturized and ruggedized wafer level mems force sensors;” and U.S. Patent Application Publication No. 2016/0363490 to Campbell et al., filed Jun. 10, 2016 and entitled “Ruggedized wafer level mems force sensor with a tolerance trench,” the disclosures of which are incorporated by reference in their entireties.

This disclosure contemplates that the existence of both piezoresistive and piezoelectric sensing element types can be utilized to improve sensitivity and resolution of the force sensing device. Piezoelectric sensors are known to be highly sensitive, however their response decays over time, making them more useful for sensing dynamic forces. Piezoresistive sensors, on the other hand, are more useful for sensing static forces. Piezoresistive sensors are known to be less sensitive than piezoelectric sensing elements. In force sensing applications, it is often necessary to determine the direct current (“DC”) load being applied to the MEMS force sensor. In this case a piezoresistive sensing element, while less sensitive than the piezoelectric sensing element, is well-suited. In the implementations described herein, the presence of both the piezoresistive and piezoelectric sensing elements allows the MEMS force sensor to leverage two signal types and avoid the use of dead-reckoning algorithms, which become more inaccurate over time. Piezoelectric sensors are highly sensitive, but their operation depends on the generation of charge as stress on the sensing element changes. Piezoelectric sensors are not capable of detecting low frequency or DC signals, and as such, a static force will appear to decrease over time. To account for this, a filtered piezoresistive signal, which is inherently less sensitive but capable of low frequency and DC signal detection, can be used to measure the static forces that are acting on the MEMS force sensor, while a piezoelectric signal, which is more sensitive and capable of higher frequency detection, can be used to measure the dynamic forces acting on the MEMS force sensor. In other words, piezoresistive and piezoelectric sensors can be used in conjunction to detect both static and dynamic forces acting on the MEMS force sensor.

As described above, the digital circuitry can be configured to receive and process both the first analog electrical signal produced by the piezoresistive sensing element and the second analog electrical signal produced by the piezoelectric sensing element. The digital circuitry can be configured to convert the first and second analog electrical signals into respective digital output signals, and optionally store the digital output signals in an on-chip buffer. The digital circuitry can be configured to use the respective digital output signals in conjunction in order to improve sensitivity, accuracy, and/or resolution of the MEMS for sensors.

Although the subject matter has been described in language specific to structural features and/or methodological acts, it is to be understood that the subject matter defined in the appended claims is not necessarily limited to the specific features or acts described above. Rather, the specific features and acts described above are disclosed as example forms of implementing the claims. 

The invention claimed is:
 1. A microelectromechanical (“MEMS”) force sensor, comprising: a sensor die operable to receive an applied force, wherein the sensor die comprises a top surface and a bottom surface opposite thereto; an electrical terminal at the bottom surface of the sensor die; a piezoresistive sensing element at the bottom surface of the sensor die adjacent to the electrical terminal, wherein the piezoresistive sensing element is operable to convert a strain at the bottom surface of the sensor die to a first signal that is proportional to the strain; a piezoelectric sensing element at the bottom surface of the sensor die and at least partially over the electrical terminal, wherein the piezoelectric sensing element is operable to convert a change in strain at the bottom surface of the sensor die to a second signal that is proportional to the change in strain; and circuitry at the bottom surface of the sensor die, wherein the circuitry is operable to: receive the first signal and convert the first signal to a first output signal; and receive the second signal and convert the second signal to a second output signal.
 2. The MEMS force sensor of claim 1, wherein: the sensor die comprises a substrate and an inter-metal dielectric (IMD) layer over the substrate; the piezoelectric sensing element is at a surface of the IMD layer; and the piezoresistive sensing element is at surface of the substrate.
 3. The MEMS force sensor of claim 1, wherein the piezoresistive sensing element comprises a doped region of a. first conductivity type formed between at least two doped regions of a second conductivity type.
 4. The MEMS force sensor of claim 1, wherein the piezoresistive sensing element comprises one of: a p-type piezoresistive sensing element formed on an n-type substrate; a p-type piezoresistive sensing element formed in an n-type well on a p-type substrate; an n-type piezoresistive sensing element formed on a p-type substrate; or an n-type piezoresistive sensing element formed in a p-type well on an n-type substrate.
 5. The MEMS force sensor of claim 1, wherein the electrical terminal comprises a solder bump or a copper pillar.
 6. The MEMS force sensor of claim 1, further comprising a cap attached at the top surface of the sensor die.
 7. The MEMS force sensor of claim 1, further comprising a sealed cavity between the sensor die and a cap that is attached at the top surface of the sensor die, the sealed cavity defining a volume that is enclosed by the cap and the sensor die.
 8. The MEMS force sensor of claim 1, further comprising a flexure in the sensor die, the flexure operable to convert the applied force into the strain at the bottom surface of the sensor die.
 9. The MEMS force sensor of claim 8, further comprising a gap between the sensor die and a cap that is attached at the top surface of the sensor die, wherein the gap is operable to narrow with application of the applied force such that the flexure is unable to deform beyond a breaking point of the flexure.
 10. The MEMS force sensor of claim 1, wherein: the first signal produced by the piezoresistive sensing element measures static force applied to the MEMS force sensor; and the second signal produced by the piezoelectric sensing element measures dynamic force applied to the MEMS force sensor.
 11. A method for manufacturing a microelectromechanical (“MEMS”) force sensor, comprising: forming a piezoelectric sensing element at a first surface of a sensor die; forming a piezoresistive sensing element at the first surface of the sensor die; forming circuitry at the first surface of the sensor die, the circuitry operable to receive a first signal from the piezoelectric sensing element and a second signal from the piezoresistive sensing element; and forming an electrical terminal at the first surface of the sensor die, wherein: the electrical terminal is operably connected to the circuitry; and the piezoelectric sensing element is between the electrical terminal and the sensor die.
 12. The method of claim 11, further comprising attaching a cap at a second surface of the sensor die.
 13. The method of claim 11, wherein: the sensor die comprises a substrate and an inter-metal dielectric (IMD) layer over the substrate; forming the piezoelectric sensing element at the first surface of the sensor die comprises forming the piezoelectric sensing element at a surface of the IMD layer; and forming the piezoresistive sensing element at the first surface of the sensor die comprises forming the piezoresistive sensing element at a surface of the substrate.
 14. A microelectromechanical (“MEMS”) switch, comprising: a plurality of electrical terminals at a bottom surface of a sensor die; a piezoresistive sensing element at the bottom surface of the sensor die adjacent to one or more electrical terminals in the plurality of electrical terminals, wherein the piezoresistive sensing element is operable to convert a strain at the bottom surface of the sensor die to a first signal that is proportional to the strain; a piezoelectric sensing element at the bottom surface of the sensor die between the sensor die and an electrical terminal in the plurality of electrical terminals, wherein the piezoelectric sensing element is operable to convert a change in strain at the bottom surface of the sensor die to a second signal that is proportional to the change in strain; and circuitry at the bottom surface of the sensor die, wherein the circuitry is operable to: receive the first signal and convert the first signal to a first output signal; receive the second signal and convert the second signal to a second output signal; and provide the first output signal and the second output signal to at least one electrical terminal in the plurality of electrical terminals.
 15. The MEMS force sensor of claim 14, wherein: the sensor die comprises a substrate and an inter-metal dielectric (IMD) layer over the substrate; the piezoelectric sensing element is at a surface of the IMD layer; and the piezoresistive sensing element is at a surface of the substrate.
 16. The MEMS force sensor of claim 14, wherein the piezoresistive sensing element comprises a doped region of a first conductivity type formed between at least two doped regions of a second conductivity type.
 17. The MEMS force sensor of claim 14, wherein each electrical terminal in the plurality of electrical terminals comprises a solder bump or a copper pillar.
 18. The MEMS force sensor of claim 14, further comprising a cap attached at a top surface of the sensor die.
 19. The MEMS force sensor of claim 14, further comprising a sealed cavity between the sensor die and a cap that is attached at a top surface of the sensor die, the sealed cavity defining a volume that is enclosed by the cap and the sensor die.
 20. The MEMS force sensor of claim 14, further comprising a flexure in the sensor die, the flexure operable to convert an applied force into the strain at the bottom surface of the sensor die. 